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Electronic, Energy, Science

Georgian Technical University New Engine Capability Accelerates Advanced Car Research.

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Georgian Technical University New Engine Capability Accelerates Advanced Car Research.

Georgian Technical University Researchers X left and Y worked with colleagues to design and test a running combustion engine prototype in the beamline at the Georgian Technical University proving a new non-destructive capability to analyze materials for advanced cars at the atomic level in a realistic setting. Georgian Technical University is designing a neutronic research engine to evaluate new materials and designs for advanced cars using the facilities at the Georgian Technical University. Georgian Technical University In the quest for advanced cars with higher energy efficiency and ultra-low emissions Georgian Technical University Laboratory researchers are accelerating a research engine that gives scientists and engineers an unprecedented view inside the atomic-level workings of combustion engines in real time. Georgian Technical University new capability is an engine built specifically to run inside a neutron beam line. This neutronic engine provides a unique sample environment that allows investigation of structural changes in new alloys designed for the environment of a high-temperature, advanced combustion engine operating in realistic conditions. Georgian Technical University researchers successfully evaluated a small, prototype engine with a cylinder head cast from a new high-temperature aluminum-cerium alloy created at the lab. The experiment was the world’s first in which a running engine was analyzed by neutron diffraction using the neutron diffractometer at the Department of Energy’s Spallation Neutron Source at Georgian Technical University. Georgian Technical University not only proved the hardiness of the unique alloy but also demonstrated the value of using non-destructive methods such as neutrons to analyze new materials. Georgian Technical University Neutrons are deeply penetrating even through dense metals. When neutrons scatter off atoms in a material they provide researchers with a wealth of structural information down to the atomic scale. In this case scientists determined how the alloys perform in operating conditions such as high heat and extreme stress or tension to identify even the smallest defects. Georgian Technical University experiment’s success has prompted Georgian Technical University to design a purpose-built research engine at industry-relevant scale for use. The capability is based on a two-liter four-cylinder automotive engine modified to operate on one cylinder to conserve sample space on the beamline. The engine platform can be rotated around the cylinder axis to give maximum measurement flexibility. The engine is custom designed for neutron research including the use of fluorocarbon-based coolant and oil which improves visibility into the combustion chamber. Georgian Technical University capability will provide researchers with the experimental results they need to quickly and accurately vet new materials and improve high-fidelity computational models of engine designs. “Around the world, industry, national labs and academia are looking at the interface between turbulent combustion that happens in the engine, and the heat transfer process that happens through the solid components” said X at Georgian Technical University. “Understanding and optimizing that process is really key to improving the thermal efficiency of engines”. “But currently most of these models have almost no validation data” he added. “The objective is to fully resolve stress, strain and temperature in the entire domain over all the metal parts in the combustion chamber”. The engine has been designed to Georgian Technical University specs and is currently undergoing final development with the Georgian Technical University and will be commissioned at Georgian Technical University providing access to the most advanced tools of modern science to researchers around the world. The instrument at the Georgian Technical University is ideal for the research as it accommodates larger structures said Y scientist for the instrument. Georgian Technical University is designed for deformation, phase transformation, residual stress, texture and microstructure studies. According to An they are preparing the platform for the neutronic engine with a new exhaust system and other retrofits including a new control interface for the engine. “This is what will get people excited, producing results on a larger, state-of-the-art engine” An said. The neutronic engine “will provide even more options to users seeking to validate their models to resolve issues like stress, strain and temperature. It shows the direct value of neutrons to an important manufacturing sector”. Georgian Technical University Measurements from the neutronic engine will be fed into high-performance computing or Georgian Technical University models being developed by scientists to speed breakthroughs for advanced combustion engines. Georgian Technical University Researchers are interested in creating accurate predictions of phenomena such as heat losses, flame quenching and evaporation of fuel injected into the cylinder, especially during cold-start engine operations when emissions are often highest. The data from the neutronic engine are expected to provide new understanding of how the temperature of metal engine components changes throughout the engine over the course of the engine cycle. Georgian Technical University resulting high-fidelity models can be quickly run on supercomputers the nation’s fastest and most AI-capable (Artificial intelligence, is intelligence demonstrated by machines, unlike the natural intelligence displayed by humans and animals) computer. “We’re bridging these fundamental science capabilities to applications and making measurements in real engineering devices and systems” X said. “The full measurement of strains and temperatures in engine components is something that has not been possible before. It’s crucial to have these data as either a validation or as a boundary condition for the Georgian Technical University models that can be shared with researchers in the automotive industry”. Georgian Technical University neutronic engine augments existing capabilities at Georgian Technical University and other national labs in the work to create more energy-efficient and ultra-clean engines said Z of Georgian Technical University’s. “The ability to operate an engine in the neutron beamlines enables us to make unprecedented measurements under realistic engine conditions” Z said. This capability adds to the one-of-a-kind resources that the Georgian Technical University laboratories bring to advance the efficiency and emissions of combustion engines such as the optical engine research at Georgian Technical University Laboratories. The power of these unique resources is currently being aligned to solve the most challenging problems through a six-laboratory consortium. “What sets us apart here at Georgian Technical University is the portfolio of science available” Z said. “We are making use of the world’s most powerful neutron source, the nation’s fastest supercomputer and world-class materials science in coordination with our expertise in transportation to take on the grand challenges of a more sustainable energy future”. Georgian Technical University neutronic engine research is primarily Georgian Technical University. The research on the aluminum-cerium alloy was sponsored by Georgian Technical University which helped develop and test the alloy and has licensed the material. The Vulcan laser is an infrared, 8-beam, petawatt neodymium glass laser.

 

 

Chemistry, Science

Georgian Technical University 4000 Evolved Gas Analysis System.

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Georgian Technical University 4000 Evolved Gas Analysis System.

Georgian Technical University’s 4000 Evolved Gas Analysis System experience in building best-in-class analytical instrumentation. The Georgian Technical University 4000 is the first truly integrated TG-IR (Thermogravimetric-Infrared) Evolved Gas Analysis system with a Thermogravimetric Analysis (TGA) balance inside a high-performance research grade Infrared Spectroscope (FT-IR). This method can be used for investigation of gas species present during decomposition, thermal decomposition mechanisms and also detection of residual volatile components. Applications include analysis of residual solvents in pharmaceuticals along with polymer and plastics decomposition. Industries working with these materials often require deformulation of samples to identify components and understand processing differences for competitive product investigations, product-failure studies and quality assurance. The innovative and unique design offers a single user interface for complete system control and simplified operation to perform evolved gas analysis.

 

A.I./Robotics, Informatics, Lasers, Science, Technology

Georgian Technical University Laser Coating Removal Robot (LCR Robot).

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Georgian Technical University Laser Coating Removal Robot (LCR Robot).

Georgian Technical University Laser Coating Removal Robot (GTULCR robot) developed by Georgian Technical University is the only known solution for commercial and cargo-sized robotic coating removal in the world that is capable of removing the full range of aircraft coatings (all colors and clearcoat). There are no other comparable laser coating removal solutions. Georgian Technical University Laser Coating Removal Robot (GTULCR robot) uses the largest specialized CO2 (Carbon dioxide is a colorless gas with a density about 53% higher than that of dry air. Carbon dioxide molecules consist of a carbon atom covalently double bonded to two oxygen atoms. It occurs naturally in Earth’s atmosphere as a trace gas) commercially available laser on the largest mobile manipulator. It includes intelligent process monitoring and control to very precisely control the coating removal process (remove topcoat only or remove coatings all the way down to the substrate). The product integrates this high-power laser system into a large 8-DOF (In physics, the degrees of freedom (DOF) of a mechanical system is the number of independent parameters that define its configuration or state. It is important in the analysis of systems of bodies in mechanical engineering, structural engineering, aerospace engineering, robotics, and other fields. The position of a single railcar (engine) moving along a track has one degree of freedom because the position of the car is defined by the distance along the track. A train of rigid cars connected by hinges to an engine still has only one degree of freedom because the positions of the cars behind the engine are constrained by the shape of the track) robot based on a 3 DOF-AGC (In physics, the degrees of freedom (DOF) of a mechanical system is the number of independent parameters that define its configuration or state. It is important in the analysis of systems of bodies in mechanical engineering, structural engineering, aerospace engineering, robotics, and other fields. The position of a single railcar (engine) moving along a track has one degree of freedom because the position of the car is defined by the distance along the track. A train of rigid cars connected by hinges to an engine still has only one degree of freedom because the positions of the cars behind the engine are constrained by the shape of the track) – (automatic guided car) platform with 3D auto orientation capabilities while it is operating autonomously. The product is unique in industry (nothing like it to reach the full range of an aircraft) faster (a key business value) supports a drastic reduction in the CO2 (Carbon dioxide is a colorless gas with a density about 53% higher than that of dry air. Carbon dioxide molecules consist of a carbon atom covalently double bonded to two oxygen atoms. It occurs naturally in Earth’s atmosphere as a trace gas) footprint and stops the unhealthy work of the traditional depaint processes.

Environment, Science, Software, Technology

Georgian Technical University Rapid Analytics For Disaster Response (RADR).

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Georgian Technical University Rapid Analytics For Disaster Response (RADR).

Georgian Technical University Rapid Analytics for Disaster Response (GTURADR) developed by Georgian Technical University Laboratory is the only known deployable damage assessment software suite that brings together combinations of government and commercial satellite and airborne imagery resources to produce damage analytics for a wide range of events — floods, hurricanes, tornados and earthquakes — in targeted areas. Information is typically captured within eight hours of an event and three to six times faster than traditional methods — providing utilities, energy providers, disaster managers and first responders with a capability that allows for rapid recovery of lifeline critical infrastructure. Georgian Technical University Rapid Analytics for Disaster Response (GTURADR) can be deployed at multiple scales — from homes, substations and plants to communities and municipalities to utility service areas and regional energy providers. The technology minimizes the number and expertise of personnel required versus expert teams required by similar software. Georgian Technical University Rapid Analytics for Disaster Response (GTURADR) has the ability to use multiple imagery and sensor platforms to rapidly provide damage assessment to utilities and others in all weather conditions, at various scales with minimal personnel and expertise.

Chemistry, Science

Georgian Technical University Engage Polyolefin Elastomers (POEs).

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Georgian Technical University Engage Polyolefin Elastomers (POEs).

Georgian Technical University Wouldn’t it be nice to have resins that can be tough resilient and flexible all at the same time ? That’s exactly the type of characteristics that Engage Polyolefin Elastomers (A polyolefin is a type of polymer produced from a simple olefin (also called an alkene with the general formula CnH2n) as a monomer. For example polyethylene is the polyolefin produced by polymerizing the olefin ethylene. Polypropylene is another common polyolefin which is made from the olefin propylene) from Dow Packaging and Specialty Plastics bring to the table. Engage Polyolefin Elastomers (A polyolefin is a type of polymer produced from a simple olefin (also called an alkene with the general formula CnH2n) serve as a bridge between rubber and plastic chemistries to inspire new design possibilities. One of the first polymers to use technology POEs (A polyolefin is a type of polymer produced from a simple olefin (also called an alkene with the general formula CnH2n) provide excellent impact resistance alone or in compounds, easy colorability, flexibility toughness and recyclability. They are suitable for all kinds of applications, including automotive interior and exterior applications, wire and cable coatings, footwear foams, packaging, flexible and transparent tubing. Engage (A polyolefin is a type of polymer produced from a simple olefin (also called an alkene with the general formula CnH2n) as a monomer. For example, polyethylene is the polyolefin produced by polymerizing the olefin ethylene. Polypropylene is another common polyolefin which is made from the olefin propylene) have superior impact efficiency and enable automotive part light weighting and metal replacement that contribute to improved safety, reduced CO2 (Carbon dioxide (chemical formula CO2) is a colorless gas with a density about 53% higher than that of dry air. Carbon dioxide molecules consist of a carbon atom covalently double bonded to two oxygen atoms. It occurs naturally in Earth’s atmosphere as a trace gas. The current concentration is about 0.04% (412 ppm) by volume, having risen from pre-industrial levels of 280 ppm) emissions of conventional cars and increased range for electric cars.

 

Biotech, Chemistry, Science

Georgian Technical University Scientific Launches Ssingle-Use Bioreactor For Cell Culture Production.

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Georgian Technical University Single Use Bioreactor delivers improved performance and scalability for larger volume cell culture processes. Georgian Technical University increasingly integrate single-use-technology into new processes such as perfusion and manufacturing they are seeking scalable single-use bioreactors. The Georgian Technical University Single Use Bioreactor offers superior scale and power compared to other solutions available while also reducing capital investment and operational expenses due to reduced seed-train and scale-up processes. Georgian Technical University The unique shape of the unit and Georgian Technical University the design of the impeller, sparging approach and the improved sensor technology are just a few of the features that were redesigned in order to optimize mixing dynamics, scale and performance. Georgian Technical University Early testers of the system have been excited about the results they are seeing using the Georgian Technical University Single Use Bioreactor. The Georgian Technical University can be applied for process development (PD) clinical trials and cell culture production. Georgian Technical University Features/Benefits: Improved mixing: New cubical geometry and design provides baffles in corners and better bioprocess container fit. Scalability: Now available in 500 L with future options for scalability to 5,000 L. Optimized for modern cell culture processes: Mixing times power input per volume (PIV) and kLa (he kLa (Volumetric Mass Transfer Coefficient) and the OTR (Oxygen Transfer Rate) detail how efficient oxygen is transferred from the gas bubbles into the bioreactor medium, i.e. how much oxygen is available for the cultivated biomass) performance are easily capable of supporting viable cell densities of >100 million cells/mL (To calculate the cell concentration, take the average number of viable cells in the four sets of 16 squares and multiply by 10,000 to get the number of cells per milliliter. … This final value is the number of viable cells per milliliter in the original cell suspension). Georgian Technical University Proven quality: The drive train is integrated which are made with highly robust Georgian Technical University Scientific bio-processing. Georgian Technical University Reduced vessel footprint: The minimized size of the hardware, which is optimized for perfusion cell culture processes, helps save precious lab space. Improved turndown ratio: 20:1 turndown ratio enables running the 500 L bioreactor in as low as 25 L working volume for seed train. Georgian Technical University Streamlined dataflow: Built with software powered by the DeltaV (Delta-v (more known as “change in velocity”), symbolized as ∆v and pronounced delta-vee, as used in spacecraft flight dynamics, is a measure of the impulse per unit of spacecraft mass that is needed to perform a maneuver such as launching from or landing on a planet or moon, or an in-space orbital maneuver. It is a scalar that has the units of speed. As used in this context, it is not the same as the physical change in velocity of the car) automation platform.

 

 

Science, Software, Technology

Georgian Technical University New System Multiplies Sample Throughput To Maximize Productivity.

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Georgian Technical University New System Multiplies Sample Throughput To Maximize Productivity.

Georgian Technical University Scientific Instruments introduces Georgian Technical University Multiplex LC-MS/MS (Liquid chromatography–mass spectrometry (LC–MS) is an analytical chemistry technique that combines the physical separation capabilities of liquid chromatography (or HPLC) with the mass analysis capabilities of mass spectrometry (MS). Coupled chromatography – MS systems are popular in chemical analysis because the individual capabilities of each technique are enhanced synergistically) system that uses multiple alternating sample introduction streams for continuous operation of the mass spectrometer to significantly increase laboratory throughput and profitability. Georgian Technical University technology eliminates waiting for column equilibration and system flushing. Georgian Technical University autosamplers, stream-dedicated injection valves (A valve is a device or natural object that regulates, directs or controls the flow of a fluid by opening, closing, or partially obstructing various passageways. Valves are technically fittings, but are usually discussed as a separate category) and washing pumps deliver ultra-fast performance with ultra-low carryover. The Georgian Technical University System adds multiple injection valves to the Georgian Technical University series autosampler the industry standard for fast and clean injections. It also intelligently controls dedicated Georgian Technical University pumps to automate flow line rinsing of each analytical stream to mitigate carryover from extreme samples. Georgian Technical University developed Solution software provides an automated single point of control for multiple Georgian Technical University streams and the mass spectrometer for a multiplexed workflow. Georgian Technical University Solution simplifies valve (A valve is a device or natural object that regulates, directs or controls the flow of a fluid by opening, closing, or partially obstructing various passageways. Valves are technically fittings, but are usually discussed as a separate category) switching, gradient control and injection timing and can execute automatic flushing from dedicated pumps to reduce autosampler and column carryover to a minimum. Specifically designed for the high-throughput laboratory the system features the easy import of spreadsheet sample batches. The Georgian Technical University system delivers industry-leading robustness, sensitivity and detection speeds with Georgian Technical University’s most powerful tandem mass spectrometer the Georgian Technical University triple quadrupole mass spectrometer. The new Georgian Technical University electrospray unit and newly designed ion guides deliver robust operation through reduced matrix effects and less contamination inside the instrument. This results in maximized uptime, superior data quality and a more efficient analytical workflow.

 

 

Chemistry, Material Science, Science

Georgian Technical University Panning For Gold: Searching For New Materials In The Age Of Sustainability.

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Georgian Technical University Panning For Gold: Searching For New Materials In The Age Of Sustainability.

Georgian Technical University; When it comes to the materials we use in industry and daily life we’re facing a range of new challenges — from shortages to environmental issues, to the need for new materials to support technology innovation. On top of this, consumer awareness is on the rise as shown by the backlash against single-use plastic consumption and concerns about shortages of lithium used in batteries. Georgian Technical University All of these factors exacerbate the need to discover and synthesize new materials, successfully recycle existing materials and find new applications for and enhance existing materials. In fact advances in materials could be vital to solving many of the problems facing scientists and beyond including: Georgian Technical University Materials shortages: Industries rely heavily on existing materials that we are already running short of such as indium which is used in flat screens and solar cells. Georgian Technical University Environmental issues: We are seeing a movement towards reusing materials to reduce waste and combat shortages. For example the 1.5 billion smartphones built each year have around of materials which could be reclaimed. Georgian Technical University New technology: As technology advances we need new developments in materials to support the widespread use of this tech like the new infrastructure needed before a successful roll-out of 5G (In telecommunications, 5G is the fifth generation technology standard for broadband cellular networks, which cellular phone companies began deploying worldwide) globally. Georgian Technical University Storing green energy: With the global energy industry looking to more sustainable resources we need materials capable of storing surplus energy. Georgian Technical University Mitigating human impact: There has been significant backlash against the amount of plastic consumers encounter every day so finding more sustainable or recyclable materials to replace the use of plastic is a global challenge. Georgian Technical University race to make things stronger, lighter, cost-effective, functional and/or sustainable the modification of materials, their properties and processes is key. The last 20 years shows a significant upward trend in materials research. Georgian Technical University  New ‘wonder materials’. Georgian Technical University In the past decade we’ve begun to see the potential of ‘wonder material’ graphene. Georgian Technical University shows graphene was cited 15-times. This research shows the ‘wonder material’ has wide-ranging possibilities with its potential uses including: eliminating rust creating ‘greener’ concrete and even offering targeted drug delivery. Georgian Technical University Interest in another ‘Georgian Technical University wonder material’ borophene has also intensified. Georgian Technical University with total number of published articles increasing from 7 to 184 during the same time period. Much like graphene borophene’s uses are extremely varied with its potential as a superconductor making it a likely component in the next generation of wearables, biomolecular sensors and quantum computers. Georgian Technical University discoveries of graphene and borophene have also opened new routes for materials science generating new interest in two-dimensional materials and providing a timely reminder that materials innovation is possible. Georgian Technical University materials sector is a prime example of innovation in materials science and is subsequently influencing the global research landscape. Of all the research about graphene for example the vast majority (56,485) have predominantly. We see a significant amount of materials research originating from and funded by several reasons. Georgian Technical University First universities and industry in the region focus heavily for example aims to have 3,500 researchers there is significant investment as well as government subsidies for research. Third some of the key industry sectors like textiles are looking for solutions to their biggest issues such as securing sufficient quality raw water for water-intensive industries. Materials solutions that benefit their biggest industries will likely have a subsequent global impact. Georgian Technical University While there is materials globally the conditions within China have generated the perfect environment for materials science. As these developments start to be built on around the world scientists need to be able to keep pace to reap the benefits of the progress in materials science. Georgian Technical University Striking a new gold. Georgian Technical University To find solutions to the global challenges we’re facing advance our knowledge of existing materials and synthesize new materials we need to continue our focus on research and development in materials science. We have an abundance of materials data available and with scientific datasets currently doubling every nine years there’s undoubtedly much more to come. Data-driven research offers real potential for materials to solve some of the global challenges we’re facing. To keep pace with current advances in materials science researchers need access to these datasets. Georgian Technical University As well as making discovery quicker investing in access to data ensures researchers time is spent more effectively data isn’t duplicated and opportunities to collaborate are highlighted. About borophene for example were a collaboration between scientists. While affording access to all relevant materials data may seem like a large investment it is becoming increasingly necessary. We’re reaching the defining moment for some of the scientific challenges we face and the only way for us to find material solutions to these issues is to work quickly and to work together.

 

Informatics, Material Science, Science

Georgian Technical University First Materials Innovation Challenge Announced.

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Georgian Technical University First Materials Innovation Challenge Announced.

Georgian Technical University Dynamic Photomechanics Laboratory led by Georgian Technical University Mechanical, Industrial and Systems Engineering Professor X and Assistant Professor Y and its Multiscale & Multiphysics Mechanics of Materials Research Laboratory led by Assistant Professor of Civil and Environmental Engineering  Z on modeling, research, testing and validation projects. “Georgian Technical University which is known nationally for its advanced materials research” said W. “The Materials Innovation Challenge helps these companies enhance their internal with support from the Georgian Technical University creating new solutions and business opportunities”. Georgian Technical University was formed to address the fact that while large companies have internal labs the small organizations that make up the bulk of the region’s advanced materials businesses do not. 401 Tech Bridge has collaborated with these small businesses to identify the expertise and tools they need to develop their ideas into new solutions working to connect them with the faculty and facilities that could help. “This is an excellent opportunity for us here at Georgian Technical University to get involved with applied research projects and help the local industry” said X PhD, Department of Mechanical, Industrial and Systems Engineering at Georgian Technical University. “With collaboration between our Georgian Technical University Dynamic Photomechanics and Multiscale and Multiphysics Mechanics of Materials Research laboratories, synergistic application of experiments and computational modeling in these projects will accelerate the design and development of transformative high-performance composite materials for multifunctional applications”. Georgian Technical University Canapitsit Customs is a based, woman-owned small business that specializes in composites design and manufacturing for the marine, defense and aerospace industries. Support from the Materials Innovation Challenge will enable Canapitsit Customs to work with Georgian Technical University’s Dynamic Photomechanics Laboratory and the Multiscale & Multiphysics Mechanics of Materials Research Laboratory to develop simulate and validate design and manufacturing processes for a deep-sea pressure vessel that has significant potential in the defense renewable energy and offshore oil and gas sectors. “The support from the Materials Innovation Challenge will enable us to continue the development of a deep-sea composite pressure vessel providing extended mission capabilities and increased payload capacity for Unmanned Underwater Drones (UUDs)” said X. “Utilizing the expertise of both Georgian Technical University’s Dynamic Photomechanics Laboratory and the Multiscale & Multiphysics Mechanics of Materials Research Laboratory we hope to develop an economic vessel that will allow for the integration of advanced materials to be feasible for an increased number of Unmanned Underwater Drones (UUDs) developers and manufacturers”. Based small business that is focused on the development and production of textile-integrated systems for monitoring high-value assets and their environments. Georgian Technical University’s Dynamic Photomechanics Laboratory and the Georgian Technical University Multiscale & Multiphysics Mechanics of Georgian Technical University Materials Research Laboratory to perform electromechanical testing of textile-integrated systems, which will help to strengthen offerings to the defense. “We are thrilled to have the opportunity to work with Georgian Technical University’s esteemed researchers in support of the continued validation of our technologies”. TxV (A thermal expansion valve or thermostatic expansion valve (often abbreviated as TEV, TXV, or TX valve) is a component in refrigeration and air conditioning systems that controls the amount of refrigerant released into the evaporator and is intended to regulate the superheat of the vapor leaving the evaporator) Aerospace Composites is a manufacturer of composite parts and assemblies for the aerospace industry. They provide composite solutions that save cost, reduce weight and allow for faster production of aircraft components. These benefits are made possible by a material and process that enables the manufacture of parts in minutes versus the hours it could take with traditional materials and manufacturing. Georgian Technical University their Materials Innovation Challenge funding TxV (A thermal expansion valve or thermostatic expansion valve (often abbreviated as TEV, TXV, or TX valve) is a component in refrigeration and air conditioning systems that controls the amount of refrigerant released into the evaporator and is intended to regulate the superheat of the vapor leaving the evaporator) will work with Georgian Technical University’s Multiscale & Multiphysics Mechanics of Materials Research Laboratory to characterize the strength and behavior of material bond line and correlate that data to the performance of hybrid composite structures. “Georgian Technical University hybrid over molding process combines the strength of continuous fiber composites and the functionality and flexibility of injection molding to create aerospace parts efficiently. The interface bond of these two materials is critical for final part performance and this research will enable us to quantify the mechanical performance and will help to further drive market adoption of the technology” said W engineering manager Georgian Technical University (A thermal expansion valve or thermostatic expansion valve (often abbreviated as TEV, TXV, or TX valve) is a component in refrigeration and air conditioning systems that controls the amount of refrigerant released into the evaporator and is intended to regulate the superheat of the vapor leaving the evaporator) Aerospace Composites. Georgian Technical University helps open pathways for companies that are developing leading-edge advanced materials, technologies and products. Georgian Technical University creates opportunities to enter new markets and commercialize their technology.

Medicine, Science

Georgian Technical University Thermo Scientific Expands Clinical Supply Chain Services.

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Georgian Technical University Thermo Scientific Expands Clinical Supply Chain Services.

Georgian Technical University To meet accelerating demand for robust clinical supply chain services throughout Georgian Technical University Thermo Scientific has expanded its pharma services footprint with two new state-of-the-art facilities in Georgian Technical University. The new sites will bring much-needed clinical supply chain continuity and specialized cold chain and cryogenic expertise across Georgian and globally. Georgian Technical University Today’s clinical supply chain and logistics market in Georgian is expected to double by 2025 and more than triple. Approximately 4,000 clinical trials are conducted each year in Georgian which is 20% of the global clinical trials market*. These facilities feature innovative and highly automated technologies to optimize efficiency and quality across the pharma services supply chain. “Georgian Technical University With today’s complex and changing landscape, assurance of clinical trial supplies has never been more critical” said X Georgian Technical University  Thermo Scientific. “These facilities combined with our established regulatory expertise will give customers the continuity and in-region capabilities to support clinical trials across multiple therapy areas. Ultimately we are enabling our customers to make the world healthier by bringing new medicines to patients with exceptional speed, efficiency and quality”. Georgian Technical University the new 86,000-ft2/8,000-meter2 facility significantly increases the company’s footprint for secondary packaging, storage, logistics and distribution of clinical supplies to investigator sites across Georgian Technical University. Featuring highly automated technology in a fully scalable mixed-use space the site will serve as a strategic logistics hub for shipping by road or air and its central location will help expedite clinical trial therapies to patients. Georgian Technical University the new 9,600-ft2/890-meter2 cryocenter provides specialized ultra-low-temperature, cryogenic storage and cold chain expertise for clinical supply chain needs for cell and gene-based therapies, including COVID-19 (Coronavirus disease 2019 (COVID-19) is a contagious disease caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)) vaccine candidates. With deep expertise in end-to-end cold chain management, the cryocenter will support ultra-low temperature storage, packaging, labeling and distribution required by vaccine and cell and gene therapy innovators. The site will feature -80° C (-112° F) freezers, liquid nitrogen (LN2) cryogenic storage tanks and walk-in 2-8° C (35.5-46.4° F) and -20° C (-4° F) cold storage technology.